Summary At 1520 Pacific daylight time, the Helijet Sikorsky S-61N/SP helicopter, serial number 61711, lifted into the hover at the Vancouver Harbour helipad for a 35-minute, visual flight rules flight to Victoria. Three crew members and 15passengers were on board. The pilot applied take-off power, and, as the helicopter began to climb vertically through about 30feet above the deck, there was a sudden and immediate loss of power from the No2 engine, accompanied by an indication of a significant engine torque split - No1 engine high and No2 engine low. Because the helicopter had not yet begun to move forward, the pilot rejected the take-off, turned the helicopter left, and landed with one engine inoperative on the northern edge of the helipad. No damage or injury occurred. Ce rapport est galement disponible en franais. Other Factual Information After the helicopter landed and was stabilized, the crew secured the No2 engine, which had shut itself down. The pilot then assessed that the passengers could not easily disembark the helicopter in the position it had landed, and he began to taxi forward to better situate the airstair door. After a short distance, however, the tail wheel ran off the edge of the deck, allowing the rear of the fuselage to fall and strike the deck edge. The aft section of the hull was damaged. The pilot could not pull the tail wheel back onto the helipad because it was caught in the deck-edge net. He instructed the first officer and the cabin attendant to deplane the passengers while he kept the main rotor running, since the airstair door alignment was now suitable. After the passengers had moved into the nearby terminal building, the first officer cut the netting cable and freed the tail wheel. The pilot then taxied to the eastern side of the helipad and shut the helicopter down. Records reveal that both pilots were trained and qualified for the flight in accordance with existing Transport Canada regulations. Records also reveal that the helicopter was maintained in accordance with existing Transport Canada regulations. The No2 engine was removed, disassembled, and examined. The associated fuel control unit and flow divider were removed, rigorously bench-tested, disassembled, and examined at an approved overhaul facility. The engine overspeed protection mechanism in the fuel control unit was tested several times. The fuel control unit functioned normally, and no defect was found in its operation or construction. In summary, no sign of defect, abnormality, or malfunction was found with the engine or its components that would have caused or contributed to the incident. The main-rotor gearbox was removed, disassembled, and examined. With the exception of the No2 (right) input freewheel unit (IFWU), no defect was found. The No2 IFWU was disassembled and examined (seeAppendixA). The IFWU gear housing was found to have been worn well beyond tolerance; the wear was eccentric, and the wear depth was greater than normally seen in a component with similar in-service life. The IFWU is essentially a clutch mechanism that provides a means to engage or disengage the engines from the main-rotor transmission system. The IFWU comprises three notable elements: a gear housing, a cam shaft, and 12rollers. In the event that an IFWU slips, the associated engine is instantly off-loaded and, as a result, frequently reaches an overspeed condition and automatically shuts down. An IFWU has a normal service life of 1250hours. Both IFWUs were installed in the main-rotor gearbox in January1999, eight months before the incident, and had accumulated 464hours of service up to the time of the incident. The maximum permitted internal dimension of an S-61 IFWU gear housing at overhaul is 3.7535inches. In places, the internal dimension of the No2 IFWU housing was 3.7595inches: the wear was 0.0059inch greater than the rejection limit. Furthermore, the wear was eccentric and 0.0045inch out of round. In comparison, the No1 (left) IFWU gear housing showed less than 0.001inch of uniform wear. Wear in the IFWU is normally caused by the unit overrunning, that is, by the main-rotor gearbox input turning faster than the driving input speed from its associated engine. This situation always occurs during main-rotor engagement when one engine is operating at lower revolutions per minute (rpm) than the other. The degree and severity of the wear can be influenced by the variables of operations and pilot technique. The issue of increasing premature removal rates for the IFWUs in the S-61 helicopter had been identified by Sikorsky Aircraft in early 1980. At that time, the manufacturer issued a customer service letter entitled Input Freewheel Unit Serviceability (MGB) (CSL-P-80-011, dated 21February1980 and revised 02April1980). The letter highlighted the probability of freewheel unit slippage being aggravated by the practice of rapid, harsh rotor engagements and predominant engine starts.1 It also recommended that the following four operational techniques be adopted by S-61operators: alternate rotor engagements between engines to reduce the frequency of overrunning and engagement impact cycles on the same IFWU, and to equalize the wear between the two IFWUs; moderate engine acceleration when matching torques for load-sharing by ensuring that pilots carry out all rotor engagements smoothly to prevent shock-loading the IFWUs; monitor the free power turbine for overshoot during flight since this is an indication of degraded performance of the IFWU; and, reduce the amount of IFWU freewheeling and rotor engagements during ground operations by sharing the load between the engines. As a result of these revised procedures being adopted, the removal rate of IFWUs improved. Helijet International, the operator of the S-61N involved in this incident, had not implemented the alternating starting procedures identified in the customer service letter. The TC-approved rotorcraft flight manual (RFM) does not include reference to the alternate starting procedure. Helijet's starting and engagement procedures were in accordance with the rotorcraft flight manual and included starting the No1 engine first, engaging the rotor, then starting the No2 engine, in that order. This practice always exposed the No2 IFWU to an overrun condition. As well, it was not uncommon at Helijet to shut down the No2 engine, stop the main rotor, then shut down the No1 engine. This practice also exposed the No2 IFWU to an overrun condition. In the recent past, the operator had used this helicopter to type-train several pilots. This training included single-engine flight operations carried out with the No2 engine retarded. For technical reasons, S-61operators prefer to reduce power on the No2 engine during simulated single-engine training. This practice again exposed the No2 IFWU to an overrun condition. Since the incident, Sikorsky Aircraft has submitted the improvements described in CSL-P-80-011 to the United States Federal Aviation Administration, for approval and incorporation into the RFM. This change will subsequently be incorporated into the TC-approved RFM.